Apparatus and methods for efficient insertion and removal of MPA markers and RDMA CRC digest

ABSTRACT

The invention relates to insertion and removal of MPA markers and RDMA CRCs in RDMA data streams, after determining the locations for these fields. An embodiment of the invention comprises a host interface, a transmit interface connected to the host interface, and a processor interface connected to both transmit and host interfaces. The host interface operates under the direction of commands received from the processor interface when processing inbound RDMA data. The host interface calculates the location of marker locations and removes the markers. The transmit interface operates under the direction of commands received from the processor interface when processing outbound RDMA data. The transmit interface calculates the positions in the outbound data where markers are to be inserted. The transmit interface them places the markers accordingly.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention described herein relates to data communications and, in particular, direct memory access (DMA).

2. Related Art

Remote DMA (RDMA) is a technology for transferring data from the memory of one computer or server to the memory of another, without involving a CPU or operating system of either machine. Because the data being transferred is not stored in application memory or in operating system buffers, RDMA is said to accomplish the transfer in a “zero-copy” manner.

RDMA is typically implemented using a suite of three protocols—RDMA Protocol (RDMAP), Direct Data Placement (DDP) and Marker PDU Aligned Framing Protocol (MPA). RDMAP provides interfaces to applications for sending and receiving data. DDP slices outgoing data into segments that fit into TCP's Maximum Segment Size (MSS), and places incoming data into destination buffers. MPA provides a framing scheme that facilitates DDP operations in identifying DDP segments.

RDMA is a “shim”, a transport protocol suite on top of TCP. RDMA leverages TCP rather than inventing its own protocols for flow control, routing, data sequencing and so on. In principle, an RDMA message can be too large to fit into one TCP segment.

MPA is a framing protocol. It adds a marker into the data stream at a stride of every 512 bytes in the TCP sequence space. Markers assist the receiver in locating the DDP/RDMA header.

Unfortunately, insertion and removal of MPA markers are not friendly operations. Inserting markers into a continuous data stream creates a disruptive shuffle of the data stream. Insertion and removal of a RDMA CRC (cyclic redundancy code) digest is also difficult to handle efficiently.

Therefore there is a need for a system and apparatus with which MPA markers and CRC digests can be easily inserted and removed during RDMA communications.

SUMMARY OF THE INVENTION

The invention described herein inserts and removes MPA markers and RDMA CRCs in RDMA data streams, after determining the locations for these fields. An embodiment of the invention comprises a host interface, a transmit interface connected to the host interface, and a processor interface connected to both transmit and host interfaces.

The host interface operates under the direction of commands received from the processor interface when processing inbound RDMA data. The host interface calculates the location of marker locations and removes the markers. CRCs are handled in a like manner.

The transmit interface operates under the direction of commands received from the processor interface when processing outbound RDMA data. The transmit interface calculates the positions in the outbound data where markers are to be inserted. The transmit interface them places the markers accordingly. CRCs are handled in a like manner.

Further embodiments, features, and advantages of the present invention, as well as the operation of the various embodiments of the present invention, are described below with reference to the accompanying figures.

BRIEF DESCRIPTION OF THE FIGURES

The accompanying drawings, which are incorporated herein and form a part of the specification, illustrate the present invention and together with the description further serve to explain the principles of the invention and to enable a person skilled in the pertinent art to make and use the invention. In the drawings, like reference numbers indicate identical or functionally similar elements. Additionally, the left-most digit of the reference number indicates a drawing in which the reference number first appears.

FIG. 1 illustrates the structure of RDMA communications in the context of the transmission control protocol.

FIG. 2 illustrates the relationship between an RDMA-capable network interface card and a host, according to an embodiment of the invention.

FIG. 3 is a block diagram of the invention as it could be implemented in the form of an integrated circuit.

FIG. 4 illustrates a processor interface, according to an embodiment of the invention.

FIG. 5 illustrates a host interface, according to an embodiment of the invention.

FIG. 6 illustrates a transmit interface, according to an embodiment of the invention.

FIG. 7 illustrates a packet format before and after processing by a data formatter, according to an embodiment of the invention.

DETAILED DESCRIPTION OF THE INVENTION

An embodiment of the present invention is now described with reference to the figures. While specific configurations and arrangements are discussed, it should be understood that this is done for illustrative purposes only. A person skilled in the relevant art will recognize that other configurations and arrangements can be used without departing from the spirit and scope of the invention. It will be apparent to a person skilled in the relevant art that this invention can also be employed in a variety of other systems and applications.

Introduction

FIG. 1 offers a schematic view of data framing with respect to RDMA. When an application issues a command for data transfer, RDMA considers all data 110 identified by the application when forming an RDMA message 120.

DDP is responsible for slicing a large RDMA message 120 into smaller segments, one of which is shown as segment 130. DDP/RDMAP prefixes each segment 130 with a DDP/RDMAP header 125. The header 125 combines RDMA control and DDP fields into a single header. The RDMA control field (not shown separately) specifies the RDMA operations. DDP fields (not shown separately) specify parameters such as the address of the destination buffers and the length of data transfer.

Especially when network packets may be received out-of-order, a receiver can use markers at fixed, known locations to quickly locate DDP headers. After recovering the DDP header, the receiver may place payload data into its destination buffer. Because each DDP segment is self-contained (in that the header includes a destination buffer address), quick data placement in the presence of out-of-order receive packets becomes feasible. This feature reduces the amount of memory required for buffering data at an adapter.

FIG. 2 illustrates the interaction between an RDMA network interface card (RNIC) 202 and a host 201. When a host application 205 is to send data via an RDMA/TCP connection, the application 205 issues a transmit request 210 to the send queue (SQ). The command includes the amount of data to be sent. The RDMA protocol suite 220 is responsible for framing the data as shown in FIG. 1, prior to processing by a TCP engine 230.

Removing markers from received RDMA packets is equally difficult. Before the RNIC can store the data into the memory locations designated by the host application, the RNIC must remove the MPA markers.

Insertion and removal of a RDMA CRC (cyclic redundancy code) digest is also difficult to handle efficiently. As shown in FIG. 1, every framed protocol data unit (PDU) is appended with a CRC digest 150.

The invention described herein is an apparatus that efficiently calculates the locations of MPA markers and RDMA CRCs, and inserts and removes them from a data stream. The invention can be a part of an RNIC, and can be embodied in an integrated circuit therein. FIG. 3 demonstrates the architecture of an ASIC that supports RDMA according to an embodiment of the invention. The illustrated design facilitates the insertion and removal of MPA markers and CRCs on the DMA paths by a transmit interface (TxIF) 310 and a host interface (HIF) module 320 respectively. The operation of these modules is coordinated in part by commands stored in a processor interface (PIF) 330.

Processor Interface (PIF)

The processor interface, an embodiment of which is shown in FIG. 4, contains a set of command queues.

TxQ 410 is a command queue for accepting data transmitting requests.

RDMA_TxCWD 420 is a queue where a protocol processor (one of protocol processors 422) inserts commands for directing the TCP engine 425 and the TxIF 310 to frame application data and send out RDMA packets.

RxQ 430 is an input queue to one or more protocol processors 422. It keeps indications from the receive interface (RxIF) 440 regarding received packets.

Protocol processors 422 receive packets via the RxQ 430. After RDMA processing, the protocol processors 422 add commands to the RDMA_RxCWD queue 450. These commands guide the DMA engines in host interface (HIF) 320 to move received packet data to designated host memory locations.

Host Interface (HIF)

FIG. 5 shows a block diagram of the host interface module 320, according to an embodiment of the invention.

When passing received data to the host, an outbound DMA engine 505 accepts commands from command queue RDMA_RxCWD 450 in the processor interface module 330. The outbound DMA engine 505 fetches packet data from the packet memory via a packet memory controller 510. Note that engine 505 is referred to here as an “outbound” engine because it is processing data that is outbound from an RNIC, even though the data is ultimately inbound to a host.

The outbound DMA engine 505 moves data through a data formatter 515, which calculates the correct MPA marker locations and removes the markers from the byte stream. In parallel, the data formatter 515 calculates the RDMAP CRC for validation purposes.

Command words in each entry of the RDMA_RxCWD queue 450 contain the following formation:

Address of the local (source) buffer, where the received packets are stored,

Address of the destination (host) buffer,

Number of bytes to copy from local buffer to host buffer,

Starting TCP sequence number for the very first byte of source data,

RDMA initial receive sequence number (rdma_irs).

The data formatter 515 will take out every data byte whose sequence number equals (rdma_irs+n*512+k), where n is an integer and k ε {0,1,2,3}. In other words, 4-byte MPA markers are inserted at a 512 bytes stride, starting at the sequence number rdma_irs.

Transmit Interface (TxIF)

When the host application is to send data, the host application writes a request to the queue TxQ 410 in PIF 330 (see FIGS. 3, 4). Referring to FIGS. 4 and 6, the protocol processors 422 will then allocate a buffer TxBuf 610 from a SRAM block 620 in the TxIF 310.

The protocol processors 422 then direct the TCP Tx engine 425 to prepare and write TCP/IP headers to the allocated buffer TxBuf 610, and instruct the inbound DMA engine 520 in HIF 320 to copy outgoing data from the host buffer into TxBuf 610. The protocol processors 422 also write an RDMA header to the allocated buffer TxBuf 610.

In an embodiment of the invention, a transmit packet in the TxBuf 610 has the layout shown on the left in FIG. 7. In the illustrated embodiment, each TxBuf is 2 KB in size. When one of protocol processors 422 issues a transmit request, the protocol processor allocates a TxBuf. The first 256 bytes will be reserved. The TCP Tx engine 425 will fill the first 128-byte region 710 with an ethernet header 715, an IP header 720, and a TCP header 725. The protocol processor will fill the next 128-byte region 730 with RDMA protocol headers 735.

In the embodiment shown, packet payload 740 starts at the point that is 256 bytes offset from the beginning of the TxBuf 610. The destination address of a Tx command word given to the inbound DMA engine 520 in HIF 320 is always set to the address of the TxBuf plus 256. The reason for this offset up is that the TCP Tx engine 425 does not understand RDMA headers. Moreover, the size of RDMA headers is not necessarily a constant.

After HIF 320 has completed copying data from the source host data buffer into the TxBuf 610, HIF 320 will signal the transmit control/unload logic 630 of the Tx interface 310. Tx interface 310 then directs its transmit control/unload logic 630 to read the packet out of the TxBuf 610 into the transmit buffer 640. Along this path, a data formatter 650 will “pack” the data byte stream, resulting in the format shown on the right of FIG. 7. The gap between the TCP header 725 and RDMA headers 735 is removed; likewise the gap between RDMA headers 735 and payload 740 is removed. Furthermore, the data formatter 650 will insert MPA markers into the packet at the right positions (such as marker 745), add padding 750 to ensure the packet ends at a word-aligned boundary, calculate and append a CRC 755, and finally calculate the checksum for the TCP/IP headers.

This is achieved by the following:

TCP engine 425 provides the TCP/IP header length information.

The protocol processor provides the following information:

the RDMA header length information,

-   -   the length of the payload to transfer,     -   the starting TCP sequence number (sseq) for the very first byte         of the outgoing TCP packet,     -   the initial RDMA send sequence number (rdma_iss).         From the length information, the data formatter 650 can gather         necessary data. Starting with the sequence number rdma_iss, data         formatter 650 will insert a marker, four bytes in length, at a         stride of every 512 bytes. Thus, the very first marker should be         inserted after the n-th bytes, where         n=512−|rdma_(—) iss−(sseq mod 512)|

Afterwards, a marker is inserted at every 512-byte stride.

Conclusion

While some embodiments of the present invention have been described above, it should be understood that it has been presented by way of examples only and not meant to limit the invention. It will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined in the appended claims. Thus, the breadth and scope of the present invention should not be limited by the above-described exemplary embodiments, but should be defined only in accordance with the following claims and their equivalents. 

1. A remote direct memory access (RDMA) network interface card (RNIC) comprising: (a) a host interface in communication with a host; (b) a transmit interface in communication with the said host interface; and (c) a processor interface in communication with the said host interface and said transmit interface, wherein (i) said host interface receives commands from said processor interface for directing processing of inbound packet data; (ii) said host interface calculates marker PDU aligned framing protocol (MPA) marker locations in said inbound packet data and removes said markers; and (iii) said transmit interface receives commands from said processor interface for directing processing of outbound packet data, receives outbound packet data from said host interface, calculates positions in outbound packet data for MPA markers, and inserts MPA markers in calculated positions in said outbound packet data.
 2. The RNIC of claim 1, wherein said processor interface comprises a plurality of command queues for queueing commands that direct the processing of said inbound and outbound packet data.
 3. The RNIC of claim 2, wherein said plurality of command queues comprises: (a) a transmit queue that accepts data transmitting requests from said host interface; (b) an RDMA transmission queue that accepts protocol processing commands that direct the transmit interface to send outbound packet data; and (c) an RDMA receive queue that accepts protocol processor commands that direct the host interface to move received inbound packet data to designated host memory locations.
 4. The RNIC of claim 1 wherein said host interface comprises a host interface data formatter that calculates locations of said MPA markers in said inbound packet data and removes said MPA markers.
 5. The RNIC of claim 4, wherein said locations of said MPA markers correspond to data byte sequence numbers calculated by the formula: rdma_irs+(n*512)+k for each k ε {0, 1, 2, 3} where n is an integer and rdma_irs is an RDMA initial sequence number.
 6. The RNIC of claim 5, wherein said commands received from said processor interface include rdma_irs.
 7. The RNIC of claim 1, wherein said transmit interface comprises a transmit interface data formatter that inserts MPA markers into said outbound packet data.
 8. The RNIC of claim 7, wherein said transmit interface data formatter inserts an MPA marker every 512 bytes, where the first MPA marker is inserted after the n^(th) byte, where n=512−|rmda_(—) iss−(sseq mod 512)| where rdma_iss is an initial rdma send sequence number, and sseq is a starting transmission control protocol (TCP) sequence number for a first byte of an outgoing TCP packet.
 9. A system for the insertion and removal of marker PDU aligned framing protocol (MPA) markers in packet data streams that are outbound and inbound, respectively, to a host, comprising: (a) a host interface in communication with the host; (b) a transmit interface in communication with said host interface; and (c) a processor interface in communication with said host interface and said transmit interface, wherein (i) said host interface receives commands from said processor interface for directing processing of inbound packet data; (ii) said host interface calculates MPA marker locations in said inbound packet data and removes said markers; and (iii) said transmit interface receives commands from said processor interface for directing processing of outbound packet data, receives outbound packet data from said host interface, calculates positions in outbound packet data for MPA markers, and inserts MPA markers in calculated positions in said outbound packet data.
 10. The system of claim 9, wherein said processor interface comprises a plurality of command queues for queueing commands that direct the processing of said inbound and outbound packet data.
 11. The system of claim 10, wherein said plurality of command queues comprises: (a) a transmit queue that accepts data transmitting requests from said host interface; (b) an RDMA transmission queue that accepts protocol processing commands that direct the transmit interface to send outbound packet data; and (c) an RDMA receive queue that accepts protocol processor commands that direct the host interface to move received inbound packet data to designated host memory locations.
 12. The system of claim 9 wherein said host interface comprises a host interface data formatter that calculates locations of said MPA markers in said inbound packet data and removes said MPA markers.
 13. The system of claim 14, wherein said locations of said MPA markers correspond to data byte sequence numbers calculated by the formula: rdma_irs+(n*512)+k for each k ε {0, 1, 2, 3} where n is an integer and rdma_irs is an RDMA initial sequence number.
 14. The system of claim 13, wherein said commands received from said processor interface include rdma_irs.
 15. The system of claim 1, wherein said transmit interface comprises a transmit interface data formatter that inserts MPA markers into said outbound packet data.
 16. The system of claim 15, wherein said transmit interface data formatter inserts an MPA marker every 512 bytes, where the first MPA marker is inserted after the n^(th) byte, where n=512−|rmda_(—i iss)−(sseq mod 512)| where rdma_iss is an initial rdma send sequence number, and sseq is a starting transmission control protocol (TCP) sequence number for a first byte of an outgoing TCP packet. 